A juvenile coelophysoid skull from the Early Jurassic of Zimbabwe, and the synonymy of Coelophysis and Syntarsus Anthea Bristowe* & Michael A. Raath Bernard Price Institute for Palaeontological Research, School of Geosciences, University of the Witwatersrand, Private Bag 3, WITS, 2050 South Africa Received 23 September 2004. Accepted 5 December 2004 INTRODUCTION Ever since the theropod Syntarsus rhodesiensis was first described (Raath 1969), a succession of authors have commented on the close morphological similarity be- tween it and Coelophysis bauri (Raath 1969, 1977; Paul 1988, 1993; Colbert 1989; Rowe 1989; Tykoski 1998; Downs 2000). Paul (1988, 1993) went so far as to propose that the two taxa belong in the same genus, and that the differ- ences advanced to justify their generic separation are questionable. Recent work on a partially disarticulated skull of a juve- nile specimen of Syntarsus, QG165, has made it possible to clarify details of the relationships between several critical cranial elements that were unclear in previous reconstruc- tions. Reconstruction of the cranium allowed reassess- ment of the characters used by Raath (1977) to distinguish Syntarsus from the closely related Coelophysis. These characters included the ‘nasal fenestra’ (reported by Raath,1977, as present in Syntarsus but absent in Coelophysis); the nature of the contact between the lachry- mal and the jugal bones; and Raath’s (1977) observation that the antorbital fenestra in Syntarsus represented 43% of total skull length. Analysis of the newly discovered skull has demolished each of these purported characters, leading us to concur with Paul (1988 1993) that i) Syntarsus is a junior synonym of Coelophysis, and ii) that the recently proposed facetious replacement name for Syntarsus (Megapnosaurus Ivie, Slipinski & Wegrzynowicz, 2001) should not stand. TAXONOMIC HISTORY Coelophysis and Syntarsus have, until recently, been clas- sified as ceratosaurian theropod dinosaurs, with C. bauri from the Late Triassic of North America and S. rhodesiensis from the Early Jurassic of Zimbabwe and South Africa. Following the work of Gauthier (1986), these taxa were suggested to belong to a monophyletic clade known as Ceratosauria. However, more recent works by a number of authors (Sereno 1997, 1999; Holtz 2000; Wilson et al. 2003; Rauhut 2003) have re-evaluated theropod interrela- tionships. For example, Rauhut (2003) proposed that Ceratosauria sensu Gauthier (1986) is paraphyletic and that the taxa usually grouped as ceratosaurs instead form two monophyletic clades that represent successive out- groups to the Tetanurae. The most basal clade is the Coelophysoidea from the Upper Triassic of the Chinle Formation in the U.S.A. to the Early Jurassic of ‘Stormberg Group’ equivalents in southern Africa. The second clade of basal theropods, comprising a more restricted Ceratosauria (sensu Rauhut 2003), includes Ceratosaurus, Elaphrosaurus and the abelisaurids. Rauhut (2003) has argued that there are two fundamen- tally different approaches in the reconstruction of theropod phylogeny. He has pointed out that analyses such as those of Thulborn (1984), Gauthier (1986) and Sereno et al. (1996) are based on predetermined lists of synapomorphic characters. The result of this approach has been robust analyses with good resolution and excep- tionally high consistency ratios. However, this method does not reflect the high degree of homoplasy that occurs in theropod phylogeny, and only partially represents a test of homology by congruence, the most reliable method of testing for homology (Rauhut 2003). The other method, preferred by Rauhut (2003), is to use as many characters as possible to test for congruence, and to estab- lish synapomorphies in this way. Consistency ratios and cladogram resolution are not nearly as impressive, and the resulting phylogenies demonstrate abundant homo- plasy (Rauhut 2003). However, the advantage of this approach is that it avoids preconceptions regarding the distribution of synapomorphic features on any particular ISSN 0078-8554 Palaeont. afr. (December 2004) 40: 31–41 31 *Author for correspondence. E-mail: bristowea@yahoo.co.uk Several authors have drawn attention to the close similarities between the neotheropod dinosaurs Coelophysis and Syntarsus. Recon- struction and analysis of a skull from a juvenile specimen of Syntarsus (collected from the Forest Sandstone Formation of Zimbabwe) show that cranial characters previously used to distinguish these taxa and justify their generic separation (namely the presence of a ‘nasal fenestra’ in Syntarsus and the length of its antorbital fenestra), were based on erroneous reconstructions of disassociated cranial elements. On the basis of this reinterpretation we conclude that Syntarsus is a junior synonym of Coelophysis. Variations are noted in three cranial characters – the length of the maxillary tooth row, the width of the base of the lachrymal and the shape of the antorbital maxillary fossa – that taken together with the chronological and geographical separation of the two taxa justify separation at species level. Keywords: Dinosaurs, Neotheropoda, Coelophysoid, taxonomy, Triassic, Jurassic. phylogeny. While character choice will always be conten- tious, Rauhut (2003) maintains the second method results in a more objective analysis. We have followed Rauhut’s approach in this study. GEOLOGICAL SETTING OF THE QG165 SKULL All known Syntarsus-bearing localities in Zimbabwe are in the fine-grained, pale, buff-coloured Forest Sandstone Formation (Raath 1969, 1977). Based on lithostratigraphic correlation, the Forest Sandstone Formation may be the equivalent of the upper part of the ‘Stormberg Group’ of the main Karoo Basin in South Africa (Olsen & Galton 1984). The ‘Stormberg Group’ comprises the Molteno, Elliot and Clarens formations, and the upper ‘Stormberg’ represents the Upper Elliot and Clarens formations (Olsen & Galton 1984). Olsen and Galton suggested on the basis of comparisons with European faunal assemblages that the lower ‘Stormberg’ assemblage was Late Triassic (Carnian-Norian) in age. However, on the basis of field evidence, Lucas & Hancox (2001) have assigned the prosauropod-dominated lower Elliot Formation a Norian age. The upper ‘Stormberg’ assemblage contains more diverse tetrapod assemblages than originally suggested by Kitching & Raath (1984), and Lucas & Hancox (2001) have conservatively assigned it an Early Jurassic age (Hettangian-Pliensbachian). They also considered the overlying Clarens Formation, which contains a limited fauna of taxa common to the underlying upper Elliot assemblages, to be Early Jurassic. The upper ‘Stormberg’ assemblage broadly correlates with the upper Newark Supergroup (eastern U.S.A.), the Glen Canyon Group (southwestern U.S.A.) and the Lower Lufeng Series (China). The African coelophysoid-bearing deposits are thus separated from the North American bone-beds by a significant period of geological time and a considerable continental distance. One of the distinctive characteristics of coelophysoid deposits in both geographic locations is that they repre- sent mass burials. One of the three localities in Zimbabwe preserves numerous individuals of S. rhodesiensis (Raath 1977, 1980). Two localities in the Kayenta Formation of Arizona, U.S.A., preserved at least three and eleven indi- viduals of S. kayentakatae, respectively (Rowe 1989). The Ghost Ranch Quarry is one of the richest Mesozoic dino- saur burials yet discovered, although claims that it has yielded a thousand individuals (Schwartz & Gillette 1994) are difficult to substantiate because there are no data on minimum numbers of individuals recovered (Sullivan 1996). It is, however, accepted that the site has yielded at least hundreds of individuals of C. bauri that were buried en masse in the sediments of the Chinle Formation (Rowe et al. 1997). These mass burials occur in a variety of depositional environments (Rowe & Gauthier 1990). The Ghost Ranch Quarry fossils are found in 1-metre-thick mudstone of fluvial origin (Rowe & Gauthier 1990). The S. kayentakatae burials are preserved in overbank deposits, and the mass burial of S. rhodesiensis was found in a thin fluvial lens within aeolian deposits (Raath 1977; Rowe & Gauthier 1990), but all localities suggest water-borne deposition of the vertebrate remains. By virtue of the numbers of indi- viduals found at the Ghost Ranch and the Chitaki River sites, it can be concluded that these were catastrophic mass death events. Another exceptional feature of coelo- physoid bone-beds is their monospecificity, supporting the conclusion that coelophysoids were gregarious (Raath 1977; Colbert 1989). MATERIALS AND METHODS In this account the following institutional abbreviations are used: AMNH, American Museum of Natural History, New York, U.S.A.; CM, Carnegie Museum, Pittsburgh, U.S.A.; GR, Ruth Hall Museum of Paleontology, Ghost Ranch, New Mexico, U.S.A.; MCZ, Museum of Compara- tive Zoology, Cambridge, U.S.A.; MNA, Museum of Northern Arizona, Flagstaff, U.S.A.; QG, Zimbabwe Natu- ral History Museum, Bulawayo, Zimbabwe Specimen QG165 was found in a detached block of For- est Sandstone from the Chitaki River bone-bed (approx. 16°07’S, 29°30’E), which was collected by one of the authors (M.A.R.) in 1972, and is now housed in the collec- tions of the Natural History Museum of Zimbabwe, Bulawayo, Zimbabwe. It consists of a partially disarticu- lated almost complete skull of a juvenile specimen, lack- ing only the snout, and is associated with a number of poorly preserved postcranial elements. This study focused on the skull. The cranial elements of QG165 are closely associated, which is unusual for material from the Chitaki River site, where the bulk of the collection consists of isolated skele- tal elements that have been randomly mixed together. In spite of this, the preservation of the often delicate and fragile bones is excellent and there is no clear evidence of abrasion or predation. Although partially disarticulated as a result of postmortem collapse and drifting by gentle currents, many of the individual elements are still close to their original life positions, providing new insights as to their articular relationships. Other Syntarsus material (also collected by M.A.R.) was compared with QG165, including QG193, 194, 195, 196, 197, 202, 235, 241, 265, 278 and 307. All this material is also stored in the Zimbabwe Natural History Museum. Data on Coelophysis material used for comparison in this study was taken from Colbert (1989), in which he used AMNH 7223, 7224, 7227, 7228, 7230, 7239, 7240, 7241, 7242; MCZ4326, 4327, 4333; MNAV3315; YPM41196 and CM-C481. Other material referred to herein includes specimens of C. bauri (CM31374, a disarticulated juvenile with CM field number C-3-82-31, GR141, GR142 and GR1442: Downs 2000); and S. kayentakatae (MNA V2623: Rowe 1989; Tykoski 1998). After initial mechanical preparation of QG165 to expose the extent of the skull, it was scanned at the Sunninghill Hospital, Sandton, Johannesburg, in a series of fine slices using a Philips Multidetector MX 8000 spiral CT scanner with effective slice thickness of 0.6 mm. The resulting images were manipulated on a Philips MxView worksta- tion using maximal intensity projection imaging tech- niques and saved on CD in DICOM format. The formatted images were converted at the School of Mechanical, 32 ISSN 0078-8554 Palaeont. afr. (December 2004) 40: 31–41 Industrial and Aeronautical Engineering at the University of the Witwatersrand using the Mimics package Version 7.3, into a digital volume, which was exported to STL (stereolithographic) file format. The STL file was sent to a commercial prototyping company where a three-dimen- sional was replica was produced. This replica was used to supplement examination of those areas of QG165 which would have been endangered by further physical prepa- ration. DESCRIPTION Raath (1977) identified a posterolateral nasal process – bordering what he termed the ‘nasal fenestra’ – as a defining character of Syntarsus. In QG165, the left nasal process is disassociated from the left nasal, but the distinc- tive V-shaped embayment is preserved (Fig. 1). However, the right nasal and the right nasal process are still essen- tially in articulation with the right lachrymal (Figs 1, 2). The nasal process is similar in every respect, other than size, to that seen in a juvenile Coelophysis specimen (C38231: Downs 2000, Fig. 3). The dorsal ramus of the right lachrymal and the lateral edge of the right nasal articulate to form what could be interpreted as a slightly raised incipient parasagittal crest, similar to the longitudinal crest described by Rowe (1989) in S. kayentakatae, but on a much smaller scale (Figs 1, 2). This ‘crest’ is slight, measur- ing no more than 3 mm in height and approximately 2 mm wide at the base. The right nasal process articulates with the anterior edge of this crest. Since there is no evidence of a similar crest on the left nasal, although the nasal process itself is preserved (Fig. 1), it seems likely that the small ‘crest’ on the right side is an artefact of slight displacement and distortion of the very thin and plastic lachrymal and nasal bones. ISSN 0078-8554 Palaeont. afr. (December 2004) 40: 31–41 33 Figure 1. The right lachrymal of QG165 shown in partial articulation with the nasal and nasal process (or ‘nasal fenestra’ as described by Raath 1977) (scale divisions = mm). Figure 2. Interpretive drawing of right lachrymal of QG165 shown in contact with the nasal process and the body of the nasal, forming a small incipient crest. Compared with the flat, featureless appearance of most of the skull bones, the lachrymals are curved and sinuous. The right lachrymal articulates with the lateral margin of the right nasal and the nasal process. It is a slender L-shaped bone with an anteriorly projecting upper ramus and a ventrally projecting vertical process that expands into a footplate (Raath 1977). The base of the footplate is noticeably narrower anteroposteriorly than in Coelophysis, measuring less than 30 per cent of the height of the verti- cal arm of the lachrymal, compared to more than 30 per cent in a number of specimens of Coelophysis, most notably in the well-preserved complete skull CM31374 (Fig. 4). The medial and lateral margins of the vertical process of the right lachrymal border an anterior sulcus that tapers into a grooved lip along the lateral border as it reaches the ventral footplate. The footplate of the right lachry- mal flares into a posterolateral process and an anterior process. The anterior process is cupped and expands out- ward around a noticeable sulcus. The footplate of the left lachrymal is not preserved. When restored, the footplate of the right lachrymal would have articulated with the dorsomedial margins of the jugal and maxilla. The jugal is a long, flat, thin bone, reinforced by longitu- dinal ridges along the lateral surface (Figs 5, 6). It forms both the lateroventral border and part of the posterior border of the orbit. The bone divides into two rami poste- riorly – a dorsal ramus that articulates with the ventral process of the postorbital, and a posterior ramus that over- laps the anterior ramus of the quadratojugal (Figs 5, 6). The anterior end of the jugal tapers to a finely pointed tip, and articulates with the posterior end of the maxilla and the ventral footplate of the lachrymal. It is excluded from the antorbital fenestra. The posterior end of the jugal is forked to receive the corresponding anterior process of the quadratojugal. This reconstruction of the palatine presented herein takes into account research on palatine recesses by Witmer (1997) and by Harris (1998). The right palatine in QG165 is reconstructed as a tetraradiate element com- prised of four conjoined processes (Figs 7, 8). There is a deeply excavated fossa (Fig. 7) on the dorsal surface of the palatine and the pterygoid that Witmer (1997) terms the muscular fossa. The muscular fossa is bordered by a pro- nounced ridge that reaches anteromedially from the maxillary contact in front of the suborbital fenestra to the vomeropterygoid contact. The vomeropterygoid process is expanded and extends both anteriorly and medially, creating a surface for the origin of the M. pterygoideus, pars dorsalis (Witmer 1997). A slender tapering maxillary process extends anteriorly, ventral to the vomeroptery- goid process. The maxillary process and the vomeroptery- goid process form the posterior borders of the choana. The fourth element of the palatine is what Harris (1998) terms the medial process, which like the maxillary process is long, tapering and laterally compressed. The medial process forms the ventral border of the palatine fenestra. It is clear from this reinterpretation that Raath (1977: fig. 4h,i) inverted the disarticulated right palatine in his re- construction. If an image of the isolated palatine QG241 is rotated through 180 degrees (Fig. 9), the bone closely resembles the palatine in both QG165 (Fig. 7), and Witmer’s (1997) reconstructions of Coelophysis (Fig. 10). In addition, the palatine in QG165 was found in close associ- ation with the pterygoid and the maxilla, suggesting that it was in, or close to, its natural position, adding further support to the reconstruction proposed herein. Witmer (1997) has used the palatine of Coelophysis, CM31374, to demonstrate the presence of a muscular fossa on the pala- tine and the sharply delineated ridge (Fig. 7). Witmer’s 34 ISSN 0078-8554 Palaeont. afr. (December 2004) 40: 31–41 Figure 4. Subadult Coelophysis skull, CM31374, on which Witmer (1997) based his drawings in Fig. 10 (photograph: A. Downs) (scale bar = 8 cm). Figure 3. Isolated juvenile nasal of C. bauri C38231; anterior is towards the right of the figure (photograph: A. Downs) (scale divisions = cm). (1997) drawings are indistinguishable from the palatine of QG165 (Fig. 10). The vomer in QG165 was not preserved but the posterior ends of these long, slender elements would have contacted the elongate, anterior processes of the pterygoid. A pair of hyoids that match those described in C. bauri (Colbert 1989) and in S. kayentakatae (Rowe, 1989) is preserved in QG165; they were not initially visible but were revealed in the rapid-prototyped replica. The hyoids in QG165 are long slender rods that are slightly bowed or angled toward the centre. They taper anteriorly, and expand and flatten posteriorly. One hyoid lies in close association with the ventral edge of the left dentary and the other in association with the right dentary. Because of damage to the left dentary, it is not possible to estimate the length of the hyoids as Rowe (1989) did in S. kayentakatae, but clearly these are long slender rods that could easily have reached one third of the length of the dentary. The hyoids of QG165 differ substantially from the ele- ments identified by Raath (1977) as hyoids, lending sup- port to the suggestion by Tykoski et al. (1993) that the latter elements are in fact furculae. TAXONOMIC ANALYSIS This analysis aims to test the validity of the historical distinctions between Syntarsus and Coelophysis to deter- mine whether or not the former is a junior synonym of the latter. The technique of taxonomic analysis (compari- son of the different character states of the two taxa) was preferred over cladistic analysis because a cladistic analy- sis would only reveal that Syntarsus and Coelophysis are sister taxa. However, the analysis is based on the list of theropod characters developed by Rauhut (2003) for his comprehensive cladistic analysis. He used 224 characters, 87 of which are cranial. Four additional characters have been added to his list of characters: (88) the presence or absence of a posterolateral nasal process (what Raath 1977, termed the ‘nasal fenestra’); (89) size of the antorbital fenestra more than 40 per cent of total skull length, or less than 40 per cent; (90) width of the base of the vertical ramus of the lachrymal expressed as a percentage of its height; and (91) the presence or absence of interdental plates. Overall, this analysis reiterates the remarkable similarity between Syntarsus and Coelophysis. Of the 91 cranial char- acters used, only 13 points of doubt or difference between the two taxa emerged, most of the uncertainty caused by preservational artefacts or missing data. The remaining 78 cranial characters were identical in the two taxa. For those 13 characters where differences were noted between the genera, ten characters were scored as uncertain in Coelo- physis because they were either obscured or distorted, or ISSN 0078-8554 Palaeont. afr. (December 2004) 40: 31–41 35 Figure 6. Interpretive drawing of the right jugal of QG165, with longitudinal ridges, a delicate anterior tip and forked posteriorly. Figure 5. Right jugal of QG165, still in articulation with the quadratojugal. The right ectopterygoid articulates with the medial surface (scale divisions = mm). there was insufficient information to score the character with confidence. Most Coelophysis skulls have been so bilaterally compressed that they provide information only in lateral view, and for this reason it is difficult to establish the nature of endocranial characters. Characters dealing with the pneumatization were difficult to score for the same reason, and because Colbert (1989) provided little detail on this aspect of the morphology. Characters of the dentary teeth in Coelophysis were problematic because the jaws of most specimens are clamped shut and the upper jaw tends to obscure dentary teeth. The ten uncer- tain characters in Coelophysis are: (37), (41), (49), (53), (60), (61), (63), (72), (74) and (83) (see Appendix 1). The three characters where points of distinction were confirmed are (13), (70) and (90). Character 13 relates to the shape of the maxillary antorbital fossa: in Coelophysis it is pointed, whereas in Syntarsus it is squared. Character 70 relates to the length of the maxillary tooth row and the posterior point at which it ends: the maxillary tooth row is longer in Coelophysis than in Syntarsus. Character 90 relates to the width of the ventral base of the vertical ramus of the lachrymal in relation to its height: in Syntarsus the width of the base of the lachrymal is less than 30 per cent of the height of the vertical ramus, whereas in Coelophysis it is more than 30 per cent. DISCUSSION There are no generally accepted criteria for distinguish- ing taxonomically significant differences from mere indi- vidual variation, and Molnar (1990) cautions against the assumption that taxonomically significant differences are always expressed in the skeleton, as there is a tendency to underestimate taxonomic diversity in fossils. However, an advantage when comparing Coelophysis and Syntarsus is that the taxa are based on samples of material that are quantitatively more than adequate and qualitatively excellent, especially where Syntarsus is concerned (Raath 1990). The first step in assessing whether Syntarsus is a synonym of Coelophysis is to review Raath’s (1977) list of thirteen characters that he considered diagnostic of the taxon. Five of these relate to differences in the length of a 36 ISSN 0078-8554 Palaeont. afr. (December 2004) 40: 31–41 Figure 7. Tetraradiate right palatine bone of QG165 showing the deep muscular fossa and sharply delineated ridge as described by Witmer (1997). ‘vpp’ = vomeropterygoid process (scale divisions = mm). Figure 8. Interpretative drawing of palatine of QG165 in relation to surrounding elements (see also Figs 6 and 8). number of elements of the skull, expressed as percent- ages. Estimates given by Raath (1977) all indicate that Syntarsus is generally smaller than Coelophysis, except for the proportional length of the antorbital fenestra. Raath (1977) estimated the length of the antorbital fenestra at 43 per cent of total skull length in Syntarsus. Owing to the partial disarticulation of QG165 it is not possible to esti- mate the length of the antorbital fenestra, but Rowe (1989) estimated that the antorbital fenestra of S. kayentakatae was approximately 26 per cent of total skull length, which is similar to the figure obtained for Coelophysis (27 per cent: Colbert 1989). It is difficult to assess dental characters in QG165 because its jaws are incompletely preserved. However, Colbert (1989) noted that the upper tooth row in Coelophysis extends to a point beneath the middle of the orbit while in Syntarsus the upper tooth row extends to the posterior border of the antorbital fenestra. Also, it has not been possible to estimate ratios of skull height to length, or skull length to presacral length in QG165 because of its incompleteness: Raath’s (1977) estimates have not been accepted because the new reconstruction of the nasal and lachrymal contact proposed here would affect his ratios, making the antorbital fenestra in Syntarsus proportionally significantly smaller than he estimated. As far as the pala- tine is concerned, it is noted that Raath’s (1977) recon- struction was based on a disarticulated right palatine bone that was inverted in the reconstruction. The reconstruc- tion proposed herein follows the pattern found in most non-avian theropods as described by Witmer (1997) and Harris (1998) – it is a tetraradiate bone consisting of four conjoined processes. Secondly, the Syntarsus characters listed as definitive by Rowe (1989), (23) antorbital fenestra more than 40 per cent of total skull length, and (24) lachrymal overlaps the jugal laterally and reaches the alveolar border, must be re-exam- ined. Both characters were based on Raath’s reconstruc- tion of disarticulated cranial elements. Rowe (1989) believed that if these characters were not sustained by articulated material, the diagnosis of S. rhodesiensis might need to be reconsidered. Thirdly, it was found that Syntarsus and Coelophysis differed in only three of 91 phylogenetically informative cranial characters (see above). All these characters 13, 70 and 90 (see Appendix 1), relate to and affect the shape of the antorbital fenestra, subtly reducing its size in Syntarsus. Previously contested characters were then re-evaluated using new evidence gleaned from the reconstruction of QG165. Because the right nasal and the right lachrymal of QG165 are still esentially in articulation, it is possible to propose a different reconstruction from that given by Raath (1977). The dorsal ramus of the right lachrymal and ISSN 0078-8554 Palaeont. afr. (December 2004) 40: 31–41 37 Figure 10. Comparison of tetraradiate coelophysoid palates illustrating the muscular fossa described by Witmer (1997). A. C. bauri (CM31375) redrawn from Witmer (1997); B. C bauri (CM31374), redrawn from Witmer (1997); C. C. rhodesiensis QG165. ‘vpp’ = vomeropterygoid process. Figure 9. The right palatine of QG241, reversed left-to-right for comparison with QG165 in Fig. 7 (photograph: M.A. Raath) (scale divisions = mm). the lateral edge of the right nasal articulate in the region of the feature described above as an incipient parasagittal crest (although more likely an artefact of distortion) in a position comparable to the longitudinal crest described by Rowe (1989) in S. kayentakatae. The posterolateral nasal process (which Raath, 1977, suggested defined what he termed the ‘nasal fenestra’) articulates with the anterior edge of this slightly raised feature, which extends from the posterior end of the lachrymal to a point about mid- way along its dorsal ramus. The nasal process could be interpreted as a derived feature of neotheropods includ- ing the coelophysoids. The character is not found in basal theropods such as the Herrerasauridae, although this is not surprising since there are significant morphological disparities between the coelophysoids and the herrera- saurids (Sereno & Novas 1993; Rauhut 2003). A homolo- gous structure is found in various other derived neo- theropods such as the much younger Tyrannosaurus rex (Brochu, 2003). There is, however, an analogous structure in basal sauropodomorphs such as Plateosaurus (Galton 1984). The footplate of the lachrymal is noticeably narrower in Syntarsus than in Coelophysis, measuring less than 30 per cent of the height of the vertical arm of the lachrymal, compared with more than 30 per cent in a number of specimens of Coelophysis, most notably CM31374 (see Fig. 4), but the extent of individual variation in this charac- ter remains unknown. In the reconstruction of QG165 proposed here, the lachrymal would articulate partially with the medial surface of the jugal and maxilla. In Raath’s (1977) reconstruction the lachrymal overlaps the jugal and maxilla laterally, reaching the alveolar border, and shortening the height of the skull. In the light of the new evidence from QG165, this interpretation is patently incorrect. There are different interpretations of the jugal in coelo- physoids: according to Rowe (1989) the anterior process of the jugal of S. kayentakatae is forked; photographs of Coelophysis specimen CM 31374 show the jugal tapering to a fine point; the anterior end of the jugal in Syntarsus QG278 appears blunt, but the end is clearly broken; in Raath’s (1977) reconstruction, the lachrymal overlaps and therefore obscures the anterior end of the jugal; and Colbert (1989) makes no mention of this character at all in his monograph on Coelophysis. In view of the excellent state of preservation of the right jugal and the anterior tip of the left jugal in QG165, this character was coded as ‘tapering’ in the taxonomic analysis. This articulation between the jugal and the antorbital fenestra has also been variously interpreted but in QG165 the jugal is unambiguously excluded from the antorbital fenestra by the posterior end of the maxilla and the ventral footplate of the lachrymal. In S. rhodesiensis, Raath (1977) contended that the jugal was excluded from the antorbital fenestra by the lachrymal footplate, which overlapped the jugal. Rowe (1989) reported that the anterior end of the jugal in S. kayentakatae was excluded from the antorbital fenestra by the posterior end of the maxilla. In Colbert’s (1989) reconstruction, the anterior tip of the jugal of C. bauri reaches the rim of the antorbital fenestra, whereas in photographs of CM31374 and other Coelophysis specimens, the tapered tip of the jugal is excluded from the fenestra and this is held to be correct. The shape of the maxillary antorbital fossa (13): the snout of Syntarsus (BP/1/5278) is squared at the anterior margin, forming an angle of approximately 70 degrees to the horizontal dentigerous ramus, whereas the corre- sponding region of a cast of Coelophysis (CM31374) is pointed, forming an angle of approximately 50 degrees. The next question to consider is whether the shape of a cranial cavity such as the antorbital fenestra represents a significant functional character in coelophysoids, impor- tant enough to justify generic separation between the two taxa. Witmer (1997) advances three hypotheses for the function of the antorbital cavity: it could be to house (1) a gland, (2) a muscle, or (3) a paranasal air sac. Having tested all three hypotheses, he concludes that only a paranasal air sac would involve all the bone structure associated with the antorbital fenestra, and that the function of the air sac is simply to pneumatize bone in an opportunistic way. According to Witmer (1997), factors such as weight reduction and optimizing design are secondary effects of air sacs. On this basis characters 13, 70 and 90 do not appear sufficiently significant to justify a generic separa- tion of the taxa, although they might well be significant at species level. There are other reasons for supporting a distinction at species level, such as the geographic and chronological separation between the two taxa. Geographic separation would not of necessity imply generic differentiation, although it might promote specific divergence. In the Late Triassic, coelophysoids represented the first successful worldwide radiation of theropods (Farlow 1993; Rauhut 2003). Coelophysoids are found in both the Late Triassic and the Early Jurassic, covering a span of around 15–20 million years, from the Carnian-Norian in North America (about 220 Ma) to the Hettangian in southern Africa (about 205.7 Ma to 201.9 Ma; Harland et al. 1990). Rauhut (2003) has identified four major theropod radiations in all, with coelophysoids being replaced by ceratosaurs (sensu Rauhut 2003) and tetanurans in the Middle Jurassic. Early Mesozoic theropod faunas lived in a world where the movement from one landmass to another was possi- ble because of continental configuration and, as a result, faunas were globally rather uniform. The differences between theropod faunas became more marked with the subsequent fragmentation of Pangaea. The distinctions in faunas between Laurasia and Gondwana increased from the Triassic to the Cretaceous (Farlow 1993; Rauhut 2003), reflecting both early endemism, and the geographic sepa- ration of the continents. As an Early Mesozoic fauna, coelophysoids match the pattern of uniformity described by Fowler (1993) and Rauhut (2003), supporting the notion of an early Mesozoic supercontinental fauna (Paul 1993). The chronological separation of Coelophysis (Late Trias- sic) and Syntarsus (Early Jurassic), might be responsible for some of the minor morphological differences that do exist. Niche adaptations to local (desert) conditions in the southern African portion of Gondwana undoubtedly also 38 ISSN 0078-8554 Palaeont. afr. (December 2004) 40: 31–41 account for some part of this variation over time. We therefore conclude that Syntarsus is indeed a junior synonym of Coelophysis, as first articulated by Paul (1988), but that the current species distinctions between the Laurasian form (C. bauri) and the Gondwanan form (C. rhodesiensis) remain valid. We acknowledge, however, that being limited to study of cranial elements only, and relying largely on a single incomplete skull, the founda- tion on which these conclusions are based is not as solid as we would have preferred. But we are confident that discovery of further articulated cranial material of the Gondwanan coelophysoid material will settle the matter and show that these conclusions are correct. SYSTEMATIC PALAEONTOLOGY Class Dinosauria Owen, 1842 Order Saurischia Seeley, 1887 Suborder Theropoda Marsh, 1881 Superfamily Coelophysoidea Welles, 1984 (sensu Holtz, 1994) Family Coelophysidae Paul, 1988 Genus Coelophysis Cope, 1889 Type species Coelophysis bauri Cope 1889 (by designation: Colbert, Charig, Dodson, Gillette, Ostrom & Weishampel 1992). A holotype was not designated by Cope in 1887 and was subsequently selected by Hay in 1930. Specimen AMNH 2722, four sacral vertebrae and an associated pubic pro- cess of an ilium, was selected as the lectotype (Colbert 1989). Synonyms Tanystropheus von Meyer 1855; (partim; non T. conspicuus von Meyer 1855; T. longobardicus (Bassani, 1886); T. antiquus von Huene, 1905; T. meridensis Wild, 1980). Coelurus Cope 1887 Podokesaurus Talbot 1911 Syntarsus Raath 1969 (non Syntarsus Fairmaire 1869) Longosaurus Welles 1984 Rioarribasaurus Hunt & Lucas 1991 Megapnosaurus Ivie, Slipinski & Wegrzynowicz 2001 Diagnosis (Rauhut 2003) The diagnosis of the genus Coelophysis is founded on a hypodigm consisting of the specimens discovered by Cope and attributed to C. bauri and the species regarded as synonyms, C. longicollis and C. willistoni, as well as com- plete skeletons of C. bauri excavated at Ghost Ranch, New Mexico, by Colbert. Coelophysis differs from Eoraptor, Herrerasaurus and Staurikosaurus in the presence of pleurocoels in the dorsal vertebrae, the more elongated dorsal vertebrae, five fused sacral vertebrae, dolichoiliac ilium, presence of a small lateral projection on the distal end of the tibia and the functionally tridactyl foot with metatarsal I that is attached to metatarsal II and does not reach the ankle joint (Rauhut 2003). It differs from Gojirasaurus in the relatively lower dorsal neural spines and the significantly smaller size, from Liliensternus in the absence of the broad ridge that extends from the posterior end of the diapophyses to the posterior end of the verte- bral centra in cervical vertebrae and the smaller size, from Procompsognathus in the considerably larger overall size, and from Shuvosaurus in the lack of any derived cranial features of the latter taxon (Rauhut 2003). The postero- lateral nasal process is the same in C.bauri as in C. rhodesiensis and C. kayentakatae. Referred species C. rhodesiensis (Raath 1969) ?C. kayentakatae (Rowe, 1989) Distribution U.S.A.: Chinle Formation, Arizona, New Mexico, Petrified Forest National Park, Arizona, Kayenta Forma- tion, Rock Head, Willow Springs, Arizona Africa: Zimbabwe (Nyamandhlovu, Chitaki River, Maura River); South Africa (northeastern Free State Prov- ince) Europe: ?Wales (D. Warrener, pers. comm. to M. Raath 1984) Stratigraphic range Late Triassic: Carnian/Norian (227.4Ma 220.7Ma) – Chinle Formation Early Jurassic: Hettangian (205.7Ma 201.9Ma) – Forest Sandstone Formation, Elliot/Clarens Formation Coelophysis rhodesiensis (Raath 1969) Synonyms Syntarsus rhodesiensis Raath, 1969 Megapnosaurus rhodesiensis Ivie, Slipinski & Wegrzyno- wicz, 2001 Holotype QG1 housed in the Natural History Museum of Zimbabwe, Bulawayo, Zimbabwe. Locality and horizon of the holotype From exposures in the Kwengula stream on Southcote Farm at 19�58’S; 28�24’ 35”E, about 38km northwest of Bulawayo, Zimbabwe (Raath 1969). The Forest Sandstone of Zimbabwe correlates with the upper ‘Stormberg Group’ in South Africa, and is thus Early Jurassic in age. Revised diagnosis C. rhodesiensis is a small bipedal coelophysoid dinosaur (sensu Rauhut 2003) that can be distinguished from C. bauri by the following cranial characters: the anterior margin of the maxillary antorbital fossa in C. rhodesiensis is blunt and squared; the width of the base of the vertical ramus of the lachrymal is less than 30 per cent of its height; and the maxillary tooth row ends at the anterior rim of the lachrymal with the lower tooth row corresponding. These three characters define the margins of the antorbital fenestra, which would be proportionally smaller than the fenestra in C. bauri. We gratefully acknowledge the co-operation of the National Museums and Monuments of Zimbabwe, and especially of the Curator of Palaeontology at the Zimbabwe Natural History Museum, Darlington Munyikwa, in permitting us to borrow the specimen QG165 on which this study relies so heavily. We are similarly grateful to Alex Downs of the Ruth Hall Museum of Paleontology, Ghost Ranch, New Mexico, for generously sharing with us some of his unpublished information on Coelophysis. Paul M. Barrett is thanked for his thorough, incisive and very help- ful review of the manuscript. We are deeply grateful to Oliver W.M.Rauhut for his thoughtful comments on the MSc dissertation from which this paper is derived. ISSN 0078-8554 Palaeont. afr. (December 2004) 40: 31–41 39 REFERENCES BROCHU, C.A. 2003. Osteology of Tyrannosaurus rex: insights from a nearly complete skeleton and high-resolution Computed Tomo- graphic Analysis of the skull. Journal of Vertebrate Paleontology, 22, Sup- plement to No. 4, 1–47. COLBERT, E, CHARIG, A., DODSON, P., GILLETTE, D.D., OSTROM, J. & WEISHAMPEL, D.B. 1992. Coelurus bauri Cope, 1887 (currently Coelophysis bauri: Reptilia, Saurischia): proposed replacement of the lectotype by a neotype. Bulletin of Zoological Nomenclature, 49(4), 276–279. COLBERT E. 1989. The Triassic dinosaur Coelophysis. Bulletin Series 57, Museum of Northern Arizona Press, Flagstaff, Arizona, 1–160. COPE, E.D. 1887. A contribution to the history of the Vertebra of the Trias of North America. Proceedings of the American Philisophical Society xxiv, 209–228. COPE, E.D. 1889. On a new genus if Triassic Dnosauria. American Natu- ralist xxiii, 626. DOWNS, A. 2000. Coelophysis bauri and Syntarus rhodesiensis compared, with comments on the preparation and preservation of fossils from the Ghost Ranch Coelophysis Quarry. In: Lucas, S.G. & Heckert, A.B. (eds.), Dinosaurs of New Mexico, New Mexico Museum of Natural History and Science Bulletin No. 17, 33–37. FARLOW, J.O. 1993. On the rareness of big fierce animals: speculations about body sizes, population densities and geographic ranges of pred- atory mammals and large carnivorous dinosaurs. American Journal of Science, 293-A, 176–199. GALTON, P.M. 1984. Cranial anatomy of the prosauropod dinosaur Plateosaurus from the Knollenmergel (Middle Keuper, Upper Triassic) of Germany. Geologica et Palaeontologica, 18, 139–171. GAUTHIER, J. 1986. Saurischian monophyly and the origin of birds. In: Padian, K. (ed.), The Origin of Birds and the Evolution of Flight. Memoirs of the Californian Academy of Science, 8, 1–55. HARLAND, W.B., ARMSTRONG, R., COX, A., LORRAINE, C., SMITH, A. & SMITH, D. 1990. A Geologic Time Scale 1989. New York, Cambridge University Press. HARRIS, J.D. 1998. A re-analysis of Acrocanthosaurus atokensis, its phylo- genetic status, paleobiogeographic implications, based on a new specimen from Texas. New Mexico Museum of Natural History and Science, Bulletin 13, 8–57. HOLTZ, T.R. 1994. The phylogenetic position of the Tyrannosauridae: implications for theropod systematics. Journal of Paleontology, 68, 1100–1117. HOLTZ, T.R. 2000. Classification and evolution of the dinosaur groups. In: Paul, G.S.(ed), The Scientific American Book of Dinosaurs. New York, St Martins Press, 140–167. HUNT, A. & LUCAS, S. 1991. Rioarribasaurus new name for a Late Triassic dinosaur from New Mexico (U.S.A.). Palaeontologische Zeitschrift 65(1-2), 191–198. IVIE, M.A., SLIPINSKI, S.A. & WEGRZYNOWICZ, P. 2001. Generic homonyms in the Colydiinae (Coleoptera: Zopheridae). Insecta Mundi, 15, 63–64. KITCHING, J.W. AND RAATH, M.A., 1984. Fossils from the Elliot and Clarens formations (Karoo sequence) of the northeastern Cape, Orange Free State and Lesotho, and a suggested biozonation based on tetrapods. Palaeontologia africana, 16, 17–23. LUCAS, S.G. & HANCOX, P.J. 2001. Tetrapod-based correlation of the nonmarine Upper Triassic of southern Africa. Albertiana, 25, 5–9. MARSH, O.C. 1881. Principal characters of American Jurassic dinosaurs. American Journal of Science, Series 3, 21, 417–423 MOLNAR, R.E. 1990. Variation in theory and theropods. In: Carpenter K. & Currie P.J., (eds) Dinosaur Systematics, Approaches and Perspectives. New York, Cambridge University Press, 71–79. OLSEN, P.E. & GALTON, P.M. 1984. A review of the reptile and amphib- ian fauna assemblages from the Stormberg of southern Africa, with special emphasis on the footprints and the age of the Stormberg. Palaeontologia africana 25, 87–110. OWEN, R. 1842. Report on British fossil reptiles. Report of the British Asso- ciation for the Advancement of Science, 11, 20–204. PAUL, G.S. 1988. Predatory Dinosaurs of the World – A Complete Illustrated Guide. New York, Simon & Shuster,. PAUL, G.S. 1993. Are Syntarsus and the Whitaker quarry theropod the same genus? New Mexico Museum of Natural History & Science, Bulletin 3, 397–402. RAATH, M.A. 1969. A new coelurosaurian dinosaur from the Forest Sandstone of Rhodesia. Arnoldia (Rhodesia), 4(28), 1–25. RAATH, M.A. 1977. The anatomy of the Triassic theropod Syntarsus rhode- siensis (Saurischia: Podokesauridae) and a consideration of its biology. Un- published Ph.D. thesis, Rhodes University, Grahamstown, South Africa. RAATH, M.A. 1980. The theropod dinosaur Syntarsus (Saurischia: Podokesauridae) discovered in South Africa. South African Journal of Science, 76, 375–376. RAATH, M.A. 1990. Morphological variation in small theropods and its meaning in systematics: evidence from Syntarsus rhodesiensis. In: Carpenter K. & Currie P.J., (eds), Dinosaur Systematics, Approaches and Perspectives. New York, Cambridge University Press, 91–104. RAATH, M.A. & MUNYIKWA, D. 1999. Further material of the ceratosaurian dinosaur Syntarsus from the Elliot Formation (Early Jurassic) of South Africa, Palaeontologia africana, 35, 55–59. RAUHUT, O.W.M. 2003. The interrelationships and evolution of basal theropod dinosaurs. Special Papers in Palaeontology No. 69. London, The Palaeontological Association, 1–213. ROWE, T. 1989. A new species of the theropod dinosaur Syntarsus from the Early Jurassic Kayenta Formation of Arizona. Journal of Vertebrate Paleontology, 9(2), 125–136. ROWE, T. & GAUTHIER, J.A. 1990. Ceratosauria. In: Weishampel, D.B., Dodson, P. & Osmolska, H. (eds.), The Dinosauria. Berkeley, University of California Press, 151–168. ROWE, T., TYKOSKI, R. & HUTCHINSON, J. 1997. Ceratosauria. In: Padian K. & Currie E. (eds) Encyclopedia of Dinosaurs. New York, Aca- demic Press, 106–110 SCHWARTZ, H.L. & GILLETTE, D.D. 1994. Geology and taphonomy of the Coelophysis quarry, Upper Triassic Chinle Formation, Ghost Ranch, New Mexico. Journal of Paleontology, 68(5), 1118–1130. SEELEY, H.G. 1887. On the classification of the fossil animals commonly named Dinosauria. Proceedings of the Royal Society of London 43, 165–171. SERENO, P.C. 1997. The origin and evolution of dinosaurs. Annual Review of Earth and Planetary 25, 435–489. SERENO, P.C. 1999. A rationale for dinosaurian taxonomy. Journal of Vertebrate Paleontology 19 (4), 788–790. SERENO, P. & NOVAS, F.E. 1993. The skull and neck of the basal theropod Herrerasaurus ischigualastensis. Journal of Vertebrate Paleontol- ogy 13(4), 435–476. SERENO, P.C., WILSON, J.A., LARSSON, H.C.E., DUTHEIL, D.B. & SUES, H-D. 1994. Early Cretaceous dinosaurs from the Sahara. Science, 265, 267–271 SERENO, P.C., DUTHEIL, D.B., IAROCHENE, M., LARSSON, H.C.E., LYON, G.H., MAGWENE, P.M., SIDOR, C.A., VARRICCHIO, D.J. & WILSON, J.A. 1996. Predatory dinosaurs from the Sahara and Late Cretaceous faunal differentiation. Science 272, 986–991. SULLIVAN, R.M. 1996. The little dinosaurs of Ghost Ranch. Review. Journal of Vertebrate Paleontology 16(2), 363–366. SULLIVAN, R.M. & LUCAS, S.G. 1999. Eucoelophysis baldwini, a new theropod dinosaur from the Upper Triassic of New Mexico, and the status of the original types of Coelophysis. Journal of Vertebrate Paleontol- ogy 19(1), 81–90. TALBOT, M. 1911. Podokesaurus holyokensis, a new dinosaur from the Tri- assic of the Connecticut Valley. American Journal of Science 4, 469–479. THULBORN, R.A. 1984. The avian relationships of Archaeoptery, and the origin of birds. Zoological Journal of the Linnean Society 82, 119–158. TYKOSKI, R.S., FORSTER, C.A., ROWE, T., SAMPSON, S.D. & MUNYIKWA, D. 1993. A furcula in the coelophysid theropod Syntarsus. Journal of Vertebrate Paleontology 22(3), 728–733. TYKOSKI, R.S. 1998. The osteology of Syntarsus kayentakatae and its impli- cations for ceratosaurid phylogeny. Unpublished M.Sc thesis, University of Texas, Austin, U.S.A., 1–260. WILSON, J.A., SERENO, P.C., SRIVASTAVA, S., BHATT, D.K., KHOSLA, A. & SAHN, A. 2003. A new abelisaurid (Dinosauria, Theropoda) from the Lameta Formation (Cretaceous, Maastrichtian) of India. Contribu- tions from the Museum of Paleontology. The University of Michigan, Ann Arbor, U.S.A, 31, 1–42. WITMER, L.M. 1997. The evolution of the antorbital cavity of archosaurs: a study in soft-tissue reconstruction in the fossil record with an analy- sis of the function of pneumaticity. Society of Vertebrate Paleontology Memoir 3. Journal of Vertebrate Paleontology 17, Supplement to No. 1, 1–73. 40 ISSN 0078-8554 Palaeont. afr. (December 2004) 40: 31–41 ISSN 0078-8554 Palaeont. afr. (December 2004) 40: 31–41 41 APPENDIX I Data matrix of cranial characters based on Rauhut (2003). [(Numbers in brackets are the values scored by Rauhut (2003)] Character Coelophysis Syntarsus 1 0 0 2 1 1 3 0 0 (1) 4 1 1 5 1 1 6 2 2 7 0 0 8 1 (?) 1 9 1 1 10 0 0 11 0 0 12 1 1 13 0 (1) 1 14 0 0 15 1 1 16 0 0 17 0 0 18 0 0 19 0 0 20 0 0 21 0 0 22 1 1 23 0 (?) 0 (1) 24 1 (?) 1 (0/1) 25 0 0 26 0 0 27 1 (0) 1 (0) 28 1 1 29 1 1 30 0 0 31 0 0 32 0 0 33 0 0 34 0 0 35 0 0 36 0 (?) 0 (1) 37 ? 0 38 0 0 39 0 0 40 0 0 41 ? (?) 0 42 0 0 43 0 0 44 0 0 45 0 0 46 1 (?) 1 Character Coelophysis Syntarsus 47 0 0 48 0 (?) 0 49 ? 1 (?) 50 0 (?) 0 51 0 0 52 1 (?) 1 53 ? 0 54 0 0 55 0 (?) 0 56 1 1 57 1 1 58 0 0 59 0 (?) 0 (1) 60 ? 0 61 ? 0 62 0 0 63 ? 0 64 0 (?) 0 65 1 (?) 1 66 1 (0) 1 (0) 67 1 (?) 1 68 1 1 (?) 69 1 (0) 1 (0) 70 (0) 2 (0) 71 0 0 72 ? (0) 1 (0) 73 (0) (0) 74 ? (0) ? 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